A pre-formulation study of a polymeric solid dispersion of paclitaxel prepared using a quasi-emulsion solvent diffusion method to improve the oral bioavailability in rats.

OBJECTIVE: To preliminarily develop a surfactant-free, polymeric solid dispersion (PSD) of paclitaxel suitable for oral administration. METHODS: A co-solvent quench method was applied to screen the proper polymer matrix of the PSD which were prepared in a liquid system using a quasi-emulsion solvent diffusion method (QESDM). Three dissolution experiments and two in vivo tests in rats were used to explain the differences among the formulations. RESULTS: The theoretical solubility ratio of amorphous/crystalline PTX was 92.6 (37 °C). Hydroxypropyl methylcellulose acetate succinate (HPMCAS) was chosen as the polymer carrier of the PSD and a porous silicon dioxide [called white carbon black (WCB)] was selectable to be used to further adjust the dissolution rate. The absolute oral bioavailability (AOB, 20 mg/kg) of the three formulas [HPMCAS/paclitaxel/WCB = 4/1/0 (F1), 8/1/0 (F2) and 4/1/4 (F3), w/w/w] were 11.8, 13.6 and 25.6%, respectively. The AOB of F3 is nearly seven times higher than that (3.8%) of paclitaxel material (a control). The advantage of higher HPMCAS/paclitaxel ratio of F2 in a dissolution test was not reflected in the first in vivo test due to the relatively higher dose of polymer which could not be effectively dissolved under the limitation of intestinal environment. This was deduced from the dissolution tests and was finally validated when the oral dose of PTX (and thus polymer) was reduced. The relevant AOBs (10 mg/kg) were 10.4, 20.8 and 19.6%, respectively. CONCLUSION: The PSD is a promising formulation strategy and the QESDM is a practical preparation method to implement such formulation design.

Development of an osmotically-driven pellet coated with acrylic copolymers (Eudragit® RS 30 D) for the sustained release of oxymatrine, a freely water soluble drug used to treat stress ulcers (I): in vitro and in vivo evaluation in rabbits.

PURPOSE: To develop an osmotically-driven pellet coated with polymeric film for sustained release of oxymatrine (OMT), a freely water soluble drug. METHODS: Pellet containing OMT and sodium chloride (NaCl), an osmotically active agent, were prepared by extrusion/spheronization and then coated with acrylic copolymers (Eudragit(®) RS 30 D) by the fluidized bed coating process. In vitro release and swelling behavior studies were employed to optimize and to evaluate the sustained-release behavior from the osmotically-driven pellets with film coated. Finally, in vivo evaluation in rabbits was employed to investigate the sustained plasma level of OMT and its active metabolite matrine. RESULTS: It was found that the F3 formulation, prepared with 20% NaCl and an 8% coating level, showed a continuous NaCl-induced water influx into the pellets providing a gradual sustained release of OMT for over 12 h. Finally, we confirmed that oral OMT with sustained release led to a gradual sustained plasma profile of both OMT, with a reduction in its bioavailability, and MT with an increase in the bioavailability compared with that of oral OMT with immediate release. CONCLUSIONS: The pharmaceutical parameters obtained suggested the potential usefulness of oral OMT with sustained release for the treatment of stress ulcers, as well as reducing the risk of MT-induced side effects.

A novel surface modified nitrendipine nanocrystals with enhancement of bioavailability and stability.

In this study, chitosan, a cationic polymer with positive charge, was introduced to modify the nanocrystals of nitrendipine with negative charge. The nanocrystals were prepared via precipitation-high pressure homogenization method. Then the nanocrystals were dispersed into chitosan solution, and the free chitosan was removed by centrifugation to obtain the chitosan modified nanocrystals, which remained the same particle size. However, the zeta-potential changed to positive after modification. The physical stability of the chitosan modified nanocrystals was remarkably improved under ambient conditions. During the in vitro dissolution test, the modified nanocrystals showed a certain degree of slow-release property. In the in vivo study, the C(max) of nitrendipine remained the same, however, the T(max) delayed from 0.75 h to 1.5 h with the chitosan modified nanocrystals. The surface modification by chitosan improved the bioavailability compared with the initial nanocrystals, which had demonstrated significant improvement of bioavailability compared to the traditional coarse powder form. Based on the experimental results, modification of the nanocrystals with certain polymer was supposed to be a good method to control the in vitro and in vivo behaviors of the nanocrystals, which could further increase the bioavailability of the water insoluble drug.

α-Tocopherol succinate-modified chitosan as a micellar delivery system for paclitaxel: preparation, characterization and in vitro/in vivo evaluations.

α-Tocopherol succinate hydrophobically modified chitosan (CS-TOS) containing 17 α-tocopherol groups per 100 anhydroglucose units was synthesized by coupling reaction. The formation of CS-TOS was confirmed by (1)H NMR and FT-IR analysis. In aqueous medium, the polymer could self-aggregate to form micelles, and the critical micelle concentration (CMC) was determined to be 5.8 × 10(-3) mg/ml. Transmission electron microscopy (TEM) observation revealed that both bare and paclitaxel-loaded micelles were near spherical in shape. The mean particle size and zeta potential of drug-loaded micelles were about 78 nm and +25.7 mV, respectively. The results of DSC and XRD analysis indicated that paclitaxel was entrapped in the micelles in molecular or amorphous state. In vitro cytotoxicity and hemolysis study revealed the effectiveness and safety of this delivery system, which was further confirmed by the in vivo antitumor evaluations. It can be concluded that the CS-TOS was a potential micellar carrier for paclitaxel.

Nitrendipine nanocrystals: its preparation, characterization, and in vitro-in vivo evaluation.

The present investigation was undertaken with the objective of developing a solid formulation containing nitrendipine nanocrystals for oral delivery. Nitrendipine nanocrystals were prepared using a tandem precipitation-homogenization process. Then, spray drying, a cost-effective method very popular in industrial situations, was employed to convert the nanocrystals into a solid form. The parameters of the preparation process were investigated and optimized. The optimal process was as follows: firstly, nitrendipine/acetone solution (100 mg/ml) was added to a polyvinyl alcohol solution (1 mg/ml) at 10°C, then the pre-suspension was homogenized for 20 cycles at 1,000 bar. Both differential scanning calorimetry and X-ray diffraction analysis indicated that nitrendipine was present in crystalline form. The in vitro dissolution rate of the nanocrystals was significantly increased compared with the physical mixture and commercial tablet. The in vivo testing demonstrated that the C(max) of the nanocrystals was approximately 15-fold and 10-fold greater than that of physical mixture and commercial tablet, respectively. In addition, the AUC(0→24) of the nanocrystals was approximately 41-fold and 10-fold greater than that of physical mixture and commercial tablet, respectively.

Protamine modified metal ion-protein chelate microparticles for sustained release of interferon.

This study focuses on extending the release period of zinc-protein chelate through protamine modification. Recombinant human interferon-α-2b (rhIFN), a highly pleiotropic cytokine with a short intrinsic pharmacokinetic half-life when injected subcutaneously (∼2-6 h), was used as a model drug. Protamine modified zinc-rhIFN chelate microparticles were prepared by co-precipitating rhIFN with zinc and protamine. Introduction of protamine (2.5-20 mg/mL) into the chelation system had several prominent effects. First, percentage of chelated rhIFN was lowered (from >99% to ∼90%); second, particle size was gradually increased (from ∼0.45 µm to ∼2 µm); last but important, it extended the release period of the chelate both in vitro (complete release was retarded from 8 h to 48 h) and in vivo (t(1/2) was prolonged from 4.5 h to 15.5 h and mean residence time from 9.4 h to 29.6 h). Size-exclusion liquid chromatography and cytopathic effect inhibition assay indicated rhIFN preserved its structural and functional integrity in these chelates.

Effect of crystal size on the in vitro dissolution and oral absorption of nitrendipine in rats.

PURPOSE: To investigate the effect of crystal size on the dissolution and oral absorption of nitrendipine, a poorly soluble drug, in rats. METHODS: Five types of nitrendipine crystal suspensions with different particle sizes (200 nm, 620 nm, 2.7 microm, 4.1 microm, 20.2 microm) were prepared either by the precipitation-ultrasonication or the anti-solvent precipitation method. The simulated intestinal fluid in the fasted state (FaSSIF) was selected as the dissolution medium, and the dissolution behaviors of different nitrendipine crystals were simulated based on a Noyes-Whitney type equation. The in vivo absorption and the absolute bioavailability of the different nitrendipine crystals were evaluated in Wistar rats. RESULTS: The dissolution rate of nitrendipine was significantly increased by a reduction in particle size. The dissolution test in FaSSIF could discriminate between the differences in the dissolution rates of the different particle sizes, and the simulated results were in agreement with the observed dissolution curves. From the simulated T(50%) values (50% dissolution time), the dissolution rates of crystals with particle sizes of 200 nm, 620 nm, 2.7 microm, 4.1 microm and 20.2 microm were calculated to be 5.1 x 10(4), 1.0 x 10(4), 237, 64 and 11-fold greater than that of the raw crystals and resulted in absolute bioavailability of 61.4% 51.5%, 29.4%, 26.7%, 24.7%, respectively. The reduction in the drug particle size correlated well with incremental improvements in oral absorption. A good linear relationship was observed between the Log (T(50%)) and the absolute bioavailability of nitrendipine. CONCLUSIONS: The dissolution rate and the oral bioavailability of nitrendipine were significantly affected by the crystal size, and the oral bioavailability could be improved significantly by preparing it as nanocrystals. FaSSIF can be used to predict differences in oral absorption of crystals with different particle sizes.

Preparation of stable nitrendipine nanosuspensions using the precipitation-ultrasonication method for enhancement of dissolution and oral bioavailability.

The aim of this study was to prepare and characterize nitrendipine nanosuspensions to enhance the dissolution rate and oral bioavailability of this drug. Nanosuspensions were prepared by the precipitation-ultrasonication method. The effects of five important process parameters, i.e. the concentration of PVA in the anti-solvent, the concentration of nitrendipine in the organic phase, the precipitation temperature, the power input and the time length of ultrasonication on the particle size of nanosuspensions were investigated systematically, and the optimal values were 0.15%, 30 mg/ml, below 3 degrees C, 400 W and 15 min, respectively. The particle size and zeta potential of nanocrystals were 209 nm (+/- 9 nm) and -13.9 mV (+/-1.9 mV), respectively. The morphology of nanocrystals was found to be flaky in shape by scanning electron microscopy (SEM) observation. The X-ray powder diffraction (XRPD) and differential scanning calorimetry (DSC) analysis indicated that there was no substantial crystalline change in the nanocrystals compared with raw crystals. The in vitro dissolution rate of nitrendipine was significantly increased by reducing the particle size. The in vivo test demonstrated that the C(max) and AUC(0-->12) values of nanosuspension in rats were approximately 6.1-fold and 5.0-fold greater than that of commercial tablets, respectively.

Insulin-S.O (sodium oleate) complex-loaded PLGA nanoparticles: formulation, characterization and in vivo evaluation.

S.O (sodium oleate) is an anionic surfactant, which is able to forman ionic complex with positively charged insulin at suitable pH. In a previous study, the insulin-S.O (Ins-S.O) complex was prepared by a hydrophobic ion pairing (HIP) method to improve the apparent liposolubility of insulin. The formation of the complex was further confirmed by Zeta potential and X-ray method. Based on the preliminary study, poly(lactide-co-glycolide) (PLGA) nanoparticles harbouring Ins-S.O complex was prepared via an emulsion solvent diffusion method. The effects of key parameters such as concentration of PVA, concentration of PLGA and initial-loaded drug on the properties of the nanoparticles were investigated. The insulin encapsulation efficiency (EE(%)) reached up to 91.2% and mean diameter of the nanoparticles was sized approximately 160 nm under optimal conditions. The pharmacological effects of the nanoparticles made of PLGA (75/25, Av Mw 15,000) were further evaluated to confirm their potential suitability for oral delivery. In order to evaluate hyperglycaemic effect of the nanoparticles for oral administration, Ins-S.O complex-loaded PLGA nanoparticles (20 IU/Kg) were administered orally by force-feeding to diabetic rats. In the case of the nanoparticles, the plasma glucose level reduced to 23.85% from the initial one 12 h post-administration and this continued for 24 h. The results showed that the use of Ins-S.O complex-loaded PLGA nanoparticles is an effective method of reducing plasma glucose levels. The insulin nanoparticles also improved the glycaemic response to an oral glucose challenge.